JP2022079573A - Prosthetic heart valves with elastic support structures and related methods - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide favorable prosthetic heart valves with elastic support structures and methods related thereto.

SOLUTION: Prosthetic heart valves are described. The prosthetic heart valves have elastic leaflets and an elastic support structure. The support structure can exhibit a precursory transition from a closed position to an open position. The support structures can exhibit a sinusoidal movement profile at a base edge during the precursory transition.

SELECTED DRAWING: Figure 5A

COPYRIGHT: (C)2022,JPO&INPIT

Description

The subject matter described herein relates to a prosthetic heart valve, more specifically a prosthetic heart valve having a support structure that stores energy and actively assists in the opening and closing of leaflets.

The human heart has several valves to maintain the proper direction of blood flow through the body. The major valves of the heart are the atrioventricular (AV) valve, which includes the bicuspid (trapezius) and tricuspid valves, and the semilunar valve, which includes the aortic and pulmonary valves. When healthy, each of these valves works similarly. The valve moves back and forth between the open state (allowing blood flow) and the closed state (preventing blood flow) in response to the pressure difference that occurs on both sides of the valve.

Patient health can be at serious risk if any of these valves begin to fail. Dysfunction can be due to a variety of reasons, but typically results in either a stenosis that restricts blood flow or a regurgitation that causes blood to flow in the wrong direction. If the defect is severe, the heart valve may require replacement.

Much effort has been put into the development of replacement heart valves, notably the replacement aorta and mitral valve. The replacement valve can be percutaneously implanted via a transfemoral or transapically introduced catheter, or can be implanted directly through open heart surgery. The replacement valve comprises an array of flaps, typically processed from porcine tissue. These tissue flaps are highly inflatable or extendable. Other replacement valves, in which the flap has an artificial polymer structure, have also been proposed. In both cases, the leaflet is often held in place by a stent or support structure, which is relatively rigid (in the case of an open heart replacement valve) or highly. Being able to extend or fix to a rigid state (in the case of transcatheter valves) provides maximum support for the leaflet. However, these highly rigid support structures are generally passive structures that provide little or no active benefit to the operation of the valve itself, other than support, when controlling flow.

For these and other reasons, there is a need for improved prosthetic valves.

Provided herein are several exemplary embodiments of a prosthetic heart valve having two or more prosthetic leaflets and a synthetic elastic support structure. In many exemplary embodiments, the valve leaflets can have sufficient rigidity to transfer the load to the elastic support structure during closure. The support structure assists the valve leaflets by storing the transmitted load as potential energy and then releasing it in the form of kinetic energy at the appropriate time as it moves from the closed state to the open state. It is of elastic nature that makes it possible. In many embodiments, this transition due to the support structure is prodromal and occurs without the assistance of the leaflets. This precursory transition to the open state can result in a pressure wave that closely resembles that of a healthy natural human heart valve. Illustrative embodiments of related methods of using and manufacturing artificial valves are also described.

Other systems, devices, methods, features, and advantages of the subject matter described herein will also be apparent or obvious to those of skill in the art, depending on the following figures and examination of embodiments for carrying out the invention. Will be. All such additional systems, methods, features, and advantages are contained within this description and are within the scope of the subject matter described herein and are intended to be protected by the accompanying claims. Will be done. The features of the exemplary embodiment should not be construed as limiting the attached claims unless there is an explicit listing of those features in the claims.
The present invention provides, for example,:
(Item 1)
It ’s an artificial heart valve.
Multiple leaflets, each of which is synthetic, with a leaflet,
It is a support structure, and the support structure is
With the plurality of protrusions coupled to the plurality of leaflets,
An upstream base of the plurality of protrusions, wherein the plurality of protrusions and the base are elastic, with a support structure comprising a base.
The artificial heart valve has a closed position and an open position, and the plurality of valve tips and the support structure move between the closed position and the open position.
The artificial heart valve is configured to allow the fluid to flow in the appropriate upstream-to-downstream direction when the transvalve fluid pressure is positive, and the transvalve fluid pressure is the peak negative pressure. When the plurality of valve leaflets are configured to be in a joined state,
The artificial heart valve is configured to automatically initiate the movement of the plurality of protrusions from the closed position to the open position when the transvalve fluid pressure is a negative value below the peak negative pressure. Artificial heart valve.
(Item 2)
The artificial heart valve according to any one of items 1 and 12-31, wherein the support structure has a peripheral edge, the base having an edge extending around the peripheral edge of the support structure.
(Item 3)
Each valve tip of the plurality of valve tips has an upstream end, each protrusion of the plurality of protrusions has a downstream end, and the edge thereof is:
A first location just upstream of each downstream end of the plurality of protrusions so that the plurality of first locations are on the edge.
Provided with a second location just upstream of each upstream end of the plurality of valve leaflets so that the plurality of second locations are on the edge.
In the first time between the movement of the support structure from the closed position to the open position, each first location moves upstream and each second location moves downstream. 2. The artificial heart valve according to 2.
(Item 4)
The artificial heart valve according to item 3, wherein the first time is when the transvalve fluid pressure is 90 to 99.9% of the peak negative pressure.
(Item 5)
The artificial heart valve according to item 3, wherein the first time is when the transvalve fluid pressure is 85 to 95% of the peak negative pressure.
(Item 6)
The artificial heart valve according to item 3, wherein the first time is when the transvalve fluid pressure is 25 to 75% of the peak negative pressure.
(Item 7)
The artificial heart valve according to item 3, wherein the first time is when the transvalve fluid pressure is the negative value.
(Item 8)
As the valve valve fluid pressure transitions from 75% of the peak negative pressure to zero, each first location on the edge moves downstream and each second location on the edge is upstream. The artificial heart valve according to item 3, which moves in a direction.
(Item 9)
In immediate response to the transition of the valve valve fluid pressure from the peak negative pressure to the less negative pressure, each first location on the edge moves downstream and each second location on the edge , The artificial heart valve according to item 3, which moves in the upstream direction.
(Item 10)
The artificial heart valve according to item 3, wherein the plurality of leaflets begin to detach from the zygosity at the first time.
(Item 11)
The artificial heart valve according to item 3, wherein at the first time, each downstream end of the plurality of protrusions moves in the radial outward direction.
(Item 12)
The artificial heart valve according to any one of items 1-11 and 13-31, wherein the support structure comprises a suture cuff and one or less suture cuff flanges.
(Item 13)
The artificial heart valve according to any one of items 1-12 and 15-31, wherein the heart valve is an aortic replacement valve or a trapezius replacement valve, wherein the heart valve comprises exactly three synthetic leaflets.
(Item 14)
The artificial heart valve according to any one of items 1-12 and 15-31, wherein the heart valve is a trapezius replacement valve comprising exactly two synthetic leaflets.
(Item 15)
The artificial heart valve according to any one of items 1-14 and 16-31, wherein the support structure is not radially crushable due to placement in an intravascular delivery device.
(Item 16)
The artificial heart valve according to any one of items 1-15 and 17-31, wherein the support structure is not radially crushable due to placement within the transapical delivery device.
(Item 17)
The artificial heart valve according to any one of items 1-16 and 18-31, wherein the support structure and the plurality of flaps are formed of the same material.
(Item 18)
The artificial heart valve according to any one of items 1-17 and 19-31, wherein the support structure comprises a coating and the plurality of flaps is a continuation of the coating.
(Item 19)
The artificial heart valve according to any one of items 1-18 and 20-31, wherein the plurality of valve leaflets are not sutured to the support structure.
(Item 20)
The artificial heart valve according to any one of items 1-19 and 21-31, wherein the plurality of valve leaflets are seamlessly coupled to the support structure.
(Item 21)
The artificial heart valve according to any one of items 1-20 and 22-31, wherein the plurality of valve leaflets and the support structure are monolithic bodies.
(Item 22)
The artificial heart valve according to any one of items 1-21 and 23-31, wherein the artificial heart valve is not a part of a cardiopulmonary bypass machine or an implantable artificial heart.
(Item 23)
The artificial heart valve according to any one of items 1-22 and 24-31, wherein the artificial heart valve is not powered by an artificial power source.
(Item 24)
The support structure has an inner diameter selected from the group consisting of 17 mm (mm), 19 mm, 21 mm, 23 mm, 25 mm, 27 mm, 29 mm, and 31 mm, according to any one of items 1-23 and 25-31. Artificial heart valve.
(Item 25)
The artificial heart valve according to any one of items 1-24 and 26-31, wherein the plurality of flaps are polymers.
(Item 26)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 10 to 45 megapascals (MPa). The artificial heart valve according to any one of items 1-25 and 29-31, wherein the second elasticity is in the range of 3000 to 5000 MPa.
(Item 27)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 20 to 35 megapascals (MPa). The artificial heart valve according to any one of items 1-25 and 29-31, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 28)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 25 to 30 megapascals (MPa). The artificial heart valve according to any one of items 1-25 and 29-31, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 29)
The artificial heart valve according to any one of items 1-28, wherein the support structure has a stiffness / unit force of 600-1500 mm2.
(Item 30)
The artificial heart valve according to any one of items 1-28, wherein the support structure has a stiffness / unit force of 900 to 1400 mm2.
(Item 31)
The artificial heart valve according to any one of items 1-28, wherein the support structure has a stiffness / unit force of 1100-1300 mm2.
(Item 32)
It ’s an artificial heart valve.
Multiple leaflets, each of which is synthetic, with a leaflet,
It is a support structure, and the support structure has a peripheral edge and has a peripheral edge.
With the plurality of protrusions coupled to the plurality of leaflets,
A support structure that is located upstream of the plurality of protrusions and has an edge extending around the periphery of the support structure, wherein the plurality of protrusions and the base are elastic and include a base. Equipped with
The artificial heart valve has a closed position and an open position, and the plurality of valve tips and the support structure move between the closed position and the open position.
Each valve tip of the plurality of valve tips has an upstream end, each protrusion of the plurality of protrusions has a downstream end, and the edge thereof is:
A first location just upstream of each downstream end of the plurality of protrusions so that the plurality of first locations are on the edge.
Provided with a second location just upstream of each upstream end of the plurality of valve leaflets so that the plurality of second locations are on the edge.
In the first time between the movement of the support structure from the closed position to the open position, each first location moves upstream and each second location moves downstream, artificial. Heart valve.
(Item 33)
32. The artificial heart valve according to item 32, wherein the first time is when the transvalve fluid pressure is 90-99.9% of the peak negative pressure.
(Item 34)
32. The artificial heart valve according to item 32, wherein the first time is when the transvalve fluid pressure is 85-95% of the peak negative pressure.
(Item 35)
32. The artificial heart valve according to item 32, wherein the first time is when the transvalve fluid pressure is 25-75% of the peak negative pressure.
(Item 36)
32. The artificial heart valve according to item 32, wherein the first time is when the transvalve fluid pressure is the negative value.
(Item 37)
As the valve valve fluid pressure transitions from 75% of the peak negative pressure to zero, each first location on the edge moves downstream and each second location on the edge is upstream. 32. The artificial heart valve according to item 32, which moves in a direction.
(Item 38)
In response to the transition of the valve valve fluid pressure from the peak negative pressure to the lesser negative pressure, each first location on the edge moves downstream and each second location on the edge moves downstream. 32. The artificial heart valve according to item 32, which moves in the upstream direction.
(Item 39)
32. The artificial heart valve according to item 32, wherein the plurality of leaflets begin to detach from the zygosity at the first time.
(Item 40)
32. The artificial heart valve according to item 32, wherein at the first time, each downstream end of the plurality of protrusions moves radially outward.
(Item 41)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 10 to 45 megapascals (MPa). The artificial heart valve according to any one of items 32-40 and 44-46, wherein the second elasticity is in the range of 3000 to 5000 MPa.
(Item 42)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 20 to 35 megapascals (MPa). The artificial heart valve according to any one of items 32-40 and 44-46, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 43)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 25 to 30 megapascals (MPa). The artificial heart valve according to any one of items 32-40 and 44-46, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 44)
The artificial heart valve according to any one of items 32-43, wherein the support structure has a stiffness / unit force of 600-1500 mm2.
(Item 45)
The artificial heart valve according to any one of items 32-43, wherein the support structure has a stiffness / unit force of 900-1400 mm2.
(Item 46)
The artificial heart valve according to any one of items 32-43, wherein the support structure has a stiffness / unit force of 1100-1300 mm2.
(Item 47)
An artificial trapezius heart valve
Multiple leaflets, each of which is synthetic, with a leaflet,
It is a support structure, and the support structure has a peripheral edge and has a peripheral edge.
A plurality of processes coupled to the plurality of flaps, each of which has a downstream end, and a plurality of processes.
A base located upstream of the plurality of protrusions, wherein the plurality of protrusions and the base are elastic, with a support structure comprising a base.
The artificial heart valve has a closed position and an open position, and the plurality of valve tips and the support structure move between the closed position and the open position during valve operation.
Artificial mitral heart valves, each of the downstream ends exhibiting an instantaneous velocity ( _VICO ) of 5.10 mm / sec (mm / s) or higher in response to the transition from the closed position to the open position.
(Item 48)
The artificial trapezius heart valve according to item 39, wherein the _VICO is 5.10 mm / s to 14.50 mm / s.
(Item 49)
The artificial trapezius heart valve according to item 39 or 40, wherein the trapezius valve has an inner diameter of 27 mm.
(Item 50)
An artificial trapezius heart valve
Multiple leaflets, each of which is synthetic, with a leaflet,
It is a support structure, and the support structure has a peripheral edge and has a peripheral edge.
A plurality of processes coupled to the plurality of flaps, each of which has a downstream end, and a plurality of processes.
A base located upstream of the plurality of protrusions, wherein the plurality of protrusions and the base are elastic, with a support structure comprising a base.
The artificial heart valve has a closed position and an open position, and the plurality of valve tips and the support structure move between the closed position and the open position during valve operation.
An artificial mitral heart valve, each of the downstream ends exhibiting an instantaneous velocity ( _VICO ) of 4.10 mm / sec (mm / s) or higher in response to the transition from the open position to the closed position.
(Item 51)
The artificial trapezius heart valve according to item 50, wherein the _VICO is 4.10 mm / s to 10.00 mm / s.
(Item 52)
The artificial trapezius heart valve according to item 50 or 51, wherein the trapezius valve has an inner diameter of 27 mm.
(Item 53)
An artificial aortic heart valve
Multiple leaflets, each of which is synthetic, with a leaflet,
It is a support structure, and the support structure has a peripheral edge and has a peripheral edge.
A plurality of processes coupled to the plurality of flaps, each of which has a downstream end, and a plurality of processes.
A base located upstream of the plurality of protrusions, wherein the plurality of protrusions and the base are elastic, with a support structure comprising a base.
The artificial heart valve has a closed position and an open position, and the plurality of valve tips and the support structure move between the closed position and the open position during valve operation.
Artificial aortic heart valves, each of the downstream ends exhibiting an instantaneous velocity ( _VICO ) of 14.60 mm / sec (mm / s) or higher in response to the transition from the closed position to the open position.
(Item 54)
The artificial aortic heart valve according to item 53, wherein the _VICO is 14.60 mm / s to 40.00 mm / s.
(Item 55)
The artificial aortic heart valve according to item 53 or 54, wherein the aortic valve has an inner diameter of 23 mm.
(Item 56)
An artificial aortic heart valve
Multiple leaflets, each of which is synthetic, with a leaflet,
It is a support structure, and the support structure has a peripheral edge and has a peripheral edge.
A plurality of processes coupled to the plurality of flaps, each of which has a downstream end, and a plurality of processes.
A base located upstream of the plurality of protrusions, wherein the plurality of protrusions and the base are elastic, with a support structure comprising a base.
The artificial heart valve has a closed position and an open position, and the plurality of valve tips and the support structure move between the closed position and the open position during valve operation.
Artificial aortic heart valves, each of the downstream ends exhibiting an instantaneous velocity ( _VICO ) of 6.10 mm / sec (mm / s) or higher in response to the transition from the open position to the closed position.
(Item 57)
The artificial aortic heart valve according to item 56, wherein the _VICO is 6.10 mm / s to 15.00 mm / s.
(Item 58)
The artificial aortic heart valve according to item 56 or 57, wherein the aortic valve has an inner diameter of 23 mm.
(Item 59)
An artificial trapezius heart valve
Multiple leaflets, each of which is synthetic, with a leaflet,
It is a support structure, and the support structure has a peripheral edge and has a peripheral edge.
A plurality of processes coupled to the plurality of flaps, each of which has a downstream end, and a plurality of processes.
A base located upstream of the plurality of protrusions, wherein the plurality of protrusions and the base are elastic, with a support structure comprising a base.
The artificial heart valve has a closed position, a neutral position, and an open position, and the plurality of valve tips and the support structure have the closed position, the neutral position, and the open position during the valve operation. Transition between
Each of the downstream ends is an artificial trapezius heart valve that moves inward by 0.45 mm (mm) or more in the transition from the neutral position to the closed position.
(Item 60)
The artificial trapezius heart valve according to item 59, wherein each of the downstream ends moves inward by 0.45 mm to 1.50 mm.
(Item 61)
The artificial trapezius heart valve according to item 59 or 60, wherein the trapezius valve has an inner diameter of 27 mm.
(Item 62)
An artificial aortic heart valve
Multiple leaflets, each of which is synthetic, with a leaflet,
It is a support structure, and the support structure has a peripheral edge and has a peripheral edge.
A plurality of processes coupled to the plurality of flaps, each of which has a downstream end, and a plurality of processes.
A base located upstream of the plurality of protrusions, wherein the plurality of protrusions and the base are elastic, with a support structure comprising a base.
The artificial heart valve has a closed position, a neutral position, and an open position, and the plurality of valve tips and the support structure have the closed position, the neutral position, and the open position during the valve operation. Transition between
Each of the downstream ends is an artificial aortic heart valve that moves inward by 0.31 mm (mm) or more in the transition from the neutral position to the closed position.
(Item 63)
62. The artificial aortic heart valve according to item 62, wherein each of the downstream ends moves inward by 0.31 mm to 1.20 mm.
(Item 64)
The artificial aortic heart valve according to item 62 or 63, wherein the aortic valve has an inner diameter of 23 mm.
(Item 65)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 10 to 45 megapascals (MPa). The artificial heart valve according to any one of items 47-64 and 62-64, wherein the second elasticity is in the range of 3000 to 5000 MPa.
(Item 66)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 20 to 35 megapascals (MPa). The artificial heart valve according to any one of items 47-64 and 68-70, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 67)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 25 to 30 megapascals (MPa). The artificial heart valve according to any one of items 47-64 and 68-70, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 68)
The artificial heart valve according to any one of items 47-67, wherein the support structure has a stiffness / unit force of 600-1500 mm2.
(Item 69)
The artificial heart valve according to any one of items 47-67, wherein the support structure has a stiffness / unit force of 900 to 1400 mm2.
(Item 70)
The artificial heart valve according to any one of items 47-67, wherein the support structure has a stiffness / unit force of 1100-1300 mm2.
(Item 71)
It ’s a method,
In the process of manufacturing an artificial heart valve, the support structure comprises molding or casting a plurality of synthetic valve tips onto the support structure.
With the plurality of protrusions coupled to the plurality of leaflets,
An upstream base of the plurality of protrusions, the plurality of protrusions and said base comprising a base that is elastic.
The artificial heart valve resulting from the manufacturing process has a closed position and an open position, and the plurality of valve tips and the support structure move between the closed position and the open position.
The artificial heart valve is configured to allow the fluid to flow in the appropriate upstream-to-downstream direction when the transvalve fluid pressure is positive, and the transvalve fluid pressure is the peak negative pressure. When the plurality of valve leaflets are configured to be in a joined state,
The artificial heart valve is configured such that when the transvalve fluid pressure is a negative value less than the peak negative pressure, the plurality of protrusions automatically start moving from the closed position to the open position. The method.
(Item 72)
Molding or casting the plurality of synthetic valve tips on the support structure
Placing the support structure over the mandrel and
71. The method of item 71, comprising immersing the support structure and mandrel in a polymer.
(Item 73)
72. The method of item 72, wherein the support structure and mandrel are immersed in the polymer multiple times.
(Item 74)
72. The method of item 72, further comprising coating the support structure with the polymer prior to immersing the support structure and mandrel in the polymer.
(Item 75)
The method of items 71 and 85-103, wherein the support structure has a peripheral edge, the base comprising an edge extending around the peripheral edge of the support structure.
(Item 76)
Each valve tip of the plurality of valve tips has an upstream end, each protrusion of the plurality of protrusions has a downstream end, and the edge thereof is:
A first location just upstream of each downstream end of the plurality of protrusions so that the plurality of first locations are on the edge.
Provided with a second location just upstream of each upstream end of the plurality of valve leaflets so that the plurality of second locations are on the edge.
In the first time between the movement of the support structure from the closed position to the open position, each first location moves upstream and each second location moves downstream. The method according to 75.
(Item 77)
The method according to item 76, wherein the first time is when the transvalve fluid pressure is 90-99.9% of the peak negative pressure.
(Item 78)
The method of item 76, wherein the first time is when the valve valve fluid pressure is 85-95% of the peak negative pressure.
(Item 79)
The method according to item 76, wherein the first time is when the transvalve fluid pressure is 25-75% of the peak negative pressure.
(Item 80)
The method of item 76, wherein the first time is when the valve valve fluid pressure is the negative value.
(Item 81)
As the valve valve fluid pressure transitions from 75% of the peak negative pressure to zero, each first location on the edge moves downstream and each second location on the edge is upstream. The method of item 76, which moves in a direction.
(Item 82)
In immediate response to the transition from the peak negative pressure to the less negative pressure, each first location on the edge moves downstream and each second location on the edge moves downstream. , The method of item 76, moving upstream.
(Item 83)
76. The method of item 76, wherein the plurality of flaps begin to detach from the zygosity at the first time.
(Item 84)
The method of item 76, wherein at the first time, each downstream end of the plurality of protrusions moves radially outward.
(Item 85)
The method of any of items 71-84 and 86-103, wherein the support structure comprises a suture cuff and one or less suture cuff flanges.
(Item 86)
The method of any of items 71-85 and 87-103, wherein the heart valve is an aortic replacement valve or a trapezius replacement valve, wherein the heart valve comprises exactly three synthetic leaflets.
(Item 87)
The method of any of items 71-86 and 88-103, wherein the heart valve is a trapezius replacement valve comprising exactly two synthetic leaflets.
(Item 88)
The method of any of items 71-87 and 89-103, wherein the support structure is not radially crushable for placement within an intravascular delivery device.
(Item 89)
The method of any of items 71-88 and 90-103, wherein the support structure is not radially crushable due to placement within the transapical delivery device.
(Item 90)
The method of any of items 71-89 and 91-103, wherein the support structure and the plurality of flaps are formed of the same material.
(Item 91)
The method of any of items 71-90 and 92-103, wherein the support structure comprises a coating and the plurality of flaps is a continuation of the coating.
(Item 92)
The method of any of items 71-91 and 93-103, wherein the plurality of valve leaflets are seamlessly coupled to the support structure.
(Item 93)
The method according to any one of items 71-92 and 94-103, wherein the plurality of valve leaflets and the support structure are monolithic bodies.
(Item 94)
The method of any of items 71-93 and 95-103, wherein the artificial heart valve is not part of a cardiopulmonary bypass machine or an implantable artificial heart.
(Item 95)
The method of any of items 71-94 and 96-103, wherein the artificial heart valve is not powered by an artificial power source.
(Item 96)
27. Item 7. Method.
(Item 97)
The method of any of items 71-96 and 98-103, wherein the plurality of flaps are polymers.
(Item 98)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 10 to 45 megapascals (MPa). The method according to any one of items 71-97 and 101-103, wherein the second elasticity is in the range of 3000 to 5000 MPa.
(Item 99)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 20 to 35 megapascals (MPa). The method according to any one of items 71-97 and 101-103, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 100)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 25 to 30 megapascals (MPa). The method according to any one of items 71-97 and 101-103, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 101)
The method of any of items 71-100, wherein the support structure has a stiffness / unit force of 600-1500 mm2.
(Item 102)
The method of any of items 71-100, wherein the support structure has a stiffness / unit force of 900 to 1400 mm2.
(Item 103)
The method of any of items 71-100, wherein the support structure has a stiffness / unit force of 1100 to 1300 mm2.
(Item 104)
It ’s a method,
The artificial heart valve comprises the use of the artificial heart valve in a living body, the artificial heart valve includes a plurality of synthetic valve tips and a support structure, and the support structure is a support structure.
With the plurality of protrusions coupled to the plurality of leaflets,
An upstream base of the plurality of protrusions, the plurality of protrusions and said base comprising a base that is elastic.
The artificial heart valve has a closed position and an open position, and the plurality of valve tips and the support structure move between the closed position and the open position during use.
The artificial heart valve allows the fluid to flow in the appropriate upstream-to-downstream direction when the transvalve fluid pressure is positive, and the plurality of valve tips have a peak negative pressure on the transvalve fluid pressure. When it is, it is in a joined state and
A method of automatically initiating the movement of the plurality of protrusions from the closed position to the open position when the valve valve fluid pressure is a negative value below the peak negative pressure.
(Item 105)
The method of any of items 104 and 106-134, wherein the support structure has a peripheral edge, wherein the base comprises an edge extending around the peripheral edge of the support structure.
(Item 106)
Each valve tip of the plurality of valve tips has an upstream end, each protrusion of the plurality of protrusions has a downstream end, and the edge thereof is:
A first location just upstream of each downstream end of the plurality of protrusions so that the plurality of first locations are on the edge.
Provided with a second location just upstream of each upstream end of the plurality of valve leaflets so that the plurality of second locations are on the edge.
In the first time between the movement of the support structure from the closed position to the open position, each first location moves upstream and each second location moves downstream. The method according to 105.
(Item 107)
The method of item 106, wherein the first time is when the valve valve fluid pressure is 90-99.9% of the peak negative pressure.
(Item 108)
The method of item 106, wherein the first time is when the valve valve fluid pressure is 85-95% of the peak negative pressure.
(Item 109)
The method of item 106, wherein the first time is when the transvalve fluid pressure is 25-75% of the peak negative pressure.
(Item 110)
10. The method of item 106, wherein the first time is when the transvalve fluid pressure is the negative value.
(Item 111)
As the valve valve fluid pressure transitions from 75% of the peak negative pressure to zero, each first location on the edge moves downstream and each second location on the edge is upstream. The method of item 106, which moves in a direction.
(Item 112)
In immediate response to the transition from the peak negative pressure to the less negative pressure, each first location on the edge moves downstream and each second location on the edge moves downstream. , The method of item 106, moving upstream.
(Item 113)
10. The method of item 106, wherein the plurality of flaps begin to detach from the zygosity at the first time.
(Item 114)
10. The method of item 106, wherein at the first time, each downstream end of the plurality of protrusions moves radially outward.
(Item 115)
The method of any of items 104-114 and 116-134, wherein the support structure comprises a suture cuff and one or less suture cuff flanges.
(Item 116)
The method of any of items 104-115 and 117-134, wherein the heart valve is an aortic replacement valve or a trapezius replacement valve, wherein the heart valve comprises exactly three synthetic leaflets.
(Item 117)
The method of any of items 104-116 and 118-134, wherein the heart valve is a trapezius replacement valve comprising exactly two synthetic leaflets.
(Item 118)
The method of any of items 104-117 and 119-134, wherein the support structure is not radially crushable for placement within an intravascular delivery device.
(Item 119)
The method of any of items 104-118 and 120-134, wherein the support structure is not radially crushable due to placement within the transapical delivery device.
(Item 120)
The method of any of items 104-119 and 121-134, wherein the support structure and the plurality of flaps are formed from the same material.
(Item 121)
The method of any of items 104-120 and 122-134, wherein the support structure comprises a coating and the plurality of flaps is a continuation of the coating.
(Item 122)
The method of any of items 104-121 and 123-134, wherein the plurality of valve leaflets are seamlessly coupled to the support structure.
(Item 123)
The method of any of items 104-122 and 124-134, wherein the plurality of valve leaflets are not sutured to the support structure.
(Item 124)
The method according to any one of items 104-123 and 125-134, wherein the plurality of valve leaflets and the support structure are monolithic bodies.
(Item 125)
The method of any of items 104-124 and 126-134, wherein the artificial heart valve is not part of a cardiopulmonary bypass machine or an implantable artificial heart.
(Item 126)
The method of any of items 104-125 and 127-134, wherein the artificial heart valve is not powered by an artificial power source.
(Item 127)
10. Method.
(Item 128)
The method of any of items 104-127 and 129-134, wherein the plurality of flaps are polymers.
(Item 129)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 10 to 45 megapascals (MPa). The method of any of items 104-128 and 132-134, wherein the second elasticity is in the range of 3000-5000 MPa.
(Item 130)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 20 to 35 megapascals (MPa). The method according to any one of items 104-128 and 132-134, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 131)
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 25 to 30 megapascals (MPa). The method according to any one of items 104-128 and 132-134, wherein the second elasticity is in the range of 3300 to 3500 MPa.
(Item 132)
The method of any of items 104-131, wherein the support structure has a stiffness / unit force of 600-1500 mm2.
(Item 133)
The method of any of items 104-131, wherein the support structure has a stiffness / unit force of 900 to 1400 square millimeters.
(Item 134)
The method of any of items 104-131, wherein the support structure has a stiffness / unit force of 1100-1300 mm2.

The details of the subject matter described herein can be clarified by review of the accompanying figures, in which similar reference numbers refer to similar parts, both in terms of their structure and operation. The components in the figure are not necessarily to scale exactly, but instead the emphasis is placed on exemplifying the principles of the subject. Moreover, all illustrations are intended to convey a concept, and relative size, shape, and other detailed attributes may be schematically illustrated rather than literally or precisely.

1A-1B are a perspective view and a vertical view illustrating an exemplary embodiment of a prosthetic heart valve in a neutral position, respectively. 1A-1B are a perspective view and a vertical view illustrating an exemplary embodiment of a prosthetic heart valve in a neutral position, respectively.

2A-2C are perspective views, top-down views, and side views, respectively, illustrating exemplary embodiments of the artificial heart valve in the open position. 2A-2C are perspective views, top-down views, and side views, respectively, illustrating exemplary embodiments of the artificial heart valve in the open position. 2A-2C are perspective views, top-down views, and side views, respectively, illustrating exemplary embodiments of the artificial heart valve in the open position.

3A-3C are perspective views, top-down views, and side views, respectively, illustrating exemplary embodiments of the artificial heart valve in the closed position. 3A-3C are perspective views, top-down views, and side views, respectively, illustrating exemplary embodiments of the artificial heart valve in the closed position. 3A-3C are perspective views, top-down views, and side views, respectively, illustrating exemplary embodiments of the artificial heart valve in the closed position.

FIG. 4A is a graph of an example of ideal valve pressure vs. time.

FIG. 4B is a graph of potential energy and kinetic energy vs. time for exemplary embodiments of the support structure.

5A-5B are partial side views and perspective views of exemplary embodiments of the artificial heart valve, respectively, in which the instantaneous velocity vector is covered during the transition to the open position. 5A-5B are partial side views and perspective views of exemplary embodiments of the artificial heart valve, respectively, in which the instantaneous velocity vector is covered during the transition to the open position.

Before the subject matter is described in detail, it should be understood that the present disclosure is not limited to the particular embodiment described and is therefore, of course, variable. Also, the terminology used herein is for the purpose of describing a particular embodiment only, and the scope of the present disclosure is limited only by the appended claims. Please understand that it is not intended.

Exemplary embodiments of systems, devices, kits, and methods are provided herein with respect to valve replacement within a human or animal subject. For ease of explanation, these embodiments of the artificial heart valve are tricuspid valves that can be implanted through open heart surgery and are therefore not compressible and expandable for transcatheter delivery.

However, the subject is not limited to such embodiments, the subject being a first radial compressed state for storage within a tubular catheter and delivery from the open distal end of the catheter. And can also be applied to transcatheter implantable heart valves, which have a second radial extension for normal operation within the heart. Similarly, the subject also applies to artificial heart valves that have only two or more than three leaflets, whether or not they can be implanted through open heart surgery or transcatheter delivery. Can be applied. These prostheses may also be used to replace valves elsewhere in the patient's body outside the heart.

1A is a perspective view of an exemplary embodiment of the artificial heart valve 100, and FIG. 1B is a vertical view. The support structure 102 is coupled with a plurality of leaflets 110-1, 110-2, and 110-3. Each leaflet 110 can be separated from the other (as shown herein) or can be part of one integrated valve acrosome.

Once implanted, the valve 100 is configured to allow or allow blood to flow in the direction indicated herein along a central axis 101 extending through the interior of the valve 100. Blood can flow from the upstream (blood inlet) end 103 to the downstream (blood outlet) end 104 of the valve, but the presence of the leaflet 110 prevents (or substantially) flows in the opposite direction. Is prevented).

The support structure 102, also referred to as a frame, may have a planar or flat upstream edge (or surface) 120 in a neutral position, or has a curved or scalloped upstream edge in a neutral position (not shown). Includes an annular base portion 105 to obtain. Examples of valves with scalloped upstream edges are described and described in US Pat. No. 9,301,837, which is incorporated herein by reference in its entirety for any purpose. Here, the upstream edge 120 is also the end point of the valve 100, along a single flange 121 extending radially outward from the side wall of the valve 100. In another embodiment, the flange 121 can be positioned further downstream on the valve 100 so that it is not co-located with the upstream edge 120. The flange 121 can be used for attaching the suture cuff to the outside of the support structure 102. One of ordinary skill in the art will readily understand the design and appearance of the suture cuff as well as the methods that can be combined with the support structure 102. A plurality of flanges 121 may be included, but preferably only a single flange 121 is used to increase the flexibility of the base 105.

The support structure 102 also includes three protruding structures 106-1, 106-2, and 106-3, which can be referred to herein as protrusions or extensions. The protrusion 106 projects from the annular base portion 105 toward the downstream end 104 so that one protrusion 106 is an adjacent valve tip 110 such that the valve apex 110 and the protrusion 106 are alternately arranged around the valve 100. It exists between each pair. In an embodiment with only two leaflets 110, there will be only two protrusions 106. Each protrusion 106 tapers to the downstream end 107. Here, each downstream end 107 is also the apex or end point of the protrusion 106.

The support structure 102 includes a curved interface 108, which is where the support structure 102 meets the base of the valve leaflet 110. The base of each cusp 110 can be a physical edge such that it would be present if the cusp 110 was manufactured separately from the support structure 102 and then the two were later combined together. In the embodiments described herein, the valve 100 is manufactured with a synthetic or artificial (ie, non-tissue) valve tip 110, and the curved interface 108 has a support structure 102 and a valve tip 110, eg, various. Seamless or non-intermittent between support structure 102 and valve leaflets 110 as would be applicable if formed in a monolithic or semi-monolithic fashion using casting (eg dip casting, etc.) and molding techniques. Boundaries can be set. Exemplary embodiments of the method of manufacturing the valve 100 are described herein.

During operation, the valve 100 periodically moves between an open position, which allows blood flow through the inside of the valve, and a closed position, where the cusp 110 prevents blood flow through the inside of the valve. Each of these leaflets 110 has a free edge 111 that moves radially inward (towards the closed position) and radially outward (towards the open position). Each valve leaflet 110 also has an upstream end (or most upstream location) 112, which in this embodiment is also an upstream apex or end point of the valve tip 110.

FIGS. 1A and 1B depict a valve 100 with a valve tip 110 in a neutral position as may be exhibited during casting or other formation of the valve 100. The neutral position is the same as or similar to the stationary position of the valve 100. 2A-2C are perspective, vertical, and side views illustrating exemplary embodiments of the valve 100 in the open position, respectively. Here, in particular, in the vertical view of FIG. 2B, the free edge 111 of the valve leaflet 110 moves outward in the radial direction so as to be away from the central axis 101, creating a relatively large opening and allowing blood flow. You can see that As will be further discussed herein, the movement of the valve leaflets 110 towards this open position is not solely due to the pressure exerted by the blood and also the support structure early in the cycle. It also depends on the active movement of 102.

3A-3C show exemplary embodiments of the valve 100 in perspective, up and down, and side views, respectively, in a closed position where the protrusions 106 (eg, end 107) are closer to each other in the radial direction than the open position. Depict. Here, the free edges 111 of the valve leaflets 110 move inward in the radial direction toward the central axis 101 (not shown) and come into contact with each other. In other words, the free edges 111-1 are in contact with the free edges 111-2 and 111-3, the free edges 111-2 are in contact with the free edges 111-1 and 111-3, and the free edges 111-3 are in contact with the free edges 111-1 and 111-3. Contact with free edges 111-1 and 111-2. This position is referred to herein as the joined state of the valve leaflets 110. In this condition, blood flow in the opposite inappropriate direction (ie, downstream to upstream) is (at least substantially) prevented. One embodiment of the valve 100 can be configured with a convex valve apex-support structure interface as described in US Pat. No. 9,301,837 incorporated.

Those skilled in the art refer to leaflets that are in a joined (or fully joined) state to prevent blood flow, but when the valve 100 is in the closed position, there is a minimal negligible gap between the leaflets. It will be appreciated that this does not require absolute zygosity or absolute prevention of blood flow, as there may be limited cases. Therefore, when the valve 100 is in the closed position, at least most of the free edges 112 will be in contact with each other, and in many embodiments, the entire free edges 112 will be in contact with each other. Moreover, at short time intervals immediately prior to complete joining, the leaflets may begin to touch without being completely joined. Such a condition can be referred to as a "partial junction". Similarly, the valve leaflets may be in a partially joined state and transition to an open state at short time intervals after the valve leaflets have exited the fully joined state.

FIG. 4A is a graph illustrating an exemplary representation of ideal transvalve blood (or, eg, other fluid in a test) pressure across the leaflet 110 during part of the cardiac cycle. This graph displays a simulation or model of transvalve pressure for the mitral valve and will be explained in that context, but the graphed pressure is also applicable to the aortic valve. For the mitral valve, the transvalve pressure is generally the pressure in the left atrium minus the pressure in the left ventricle. For aortic valves, transvalve pressure is generally the pressure in the aorta minus the pressure in the left ventricle.

Region 402 indicates the period of time during which positive pressure is present across the cusp 110 and generally corresponds to the period during which the mitral valve is open (the apex 110 is not joined). In region 402, the left ventricle relaxes and a left atrial systole occurs, further filling the left ventricle with blood. This time period is generally relatively long, but here it is condensed for ease of illustration. Region 402 extends to point A, where the valve pressure transitions from positive to zero and blood stops moving in the appropriate upstream-to-downstream direction (left atrium to left ventricle).

Region 404 generally indicates a time period starting from point A where the valve pressure is zero, then negative and continues to decrease (more negative). When negative, blood is pressurized to move in the opposite direction (downstream to upstream). As the pressure transitions from zero to negative, the mitral valve begins to close. Region 404 ends at point B, which indicates the time point at which the peak negative pressure is exhibited across the valve leaflet 110. At region 404, the aortic valve opens and isotonic contraction of the left ventricle occurs.

Region 406 generally indicates the time period from point B to point C where the peak negative pressure remains generally constant. At point B, the mitral valve leaflets are completely joined. Those skilled in the art will recognize that the pressure traces within regions 402-410 have a generally constant slope (or no slope as in region 404) as FIG. 4A is a graph of ideal valve pressure. There will be. In a real heart, these valve pressures will be more different than would be expected in a complex natural environment. Therefore, the pressure in the region 406 and others fluctuates in practice, and the region 406 is considered as a transition region where the blood pressure exhibits either a discrete peak or a peak curve prior to becoming less negative. obtain.

Region 408 indicates a time period starting from point C where the pressure is steadily increasing (less negative) until it reaches zero at point D. In region 408, isotonic relaxation of the left ventricle occurs, the aortic valve closes, and the natural mitral valve remains closed.

Region 410 generally indicates a time period starting from point D where the pressure increases from zero and becomes more positive. When positive, the blood is pressurized to move in the proper direction (upstream to downstream). As the pressure transitions positively from zero, the natural mitral valve begins to break away from the zygosity. Region 410 generally corresponds to the start of a new cardiac cycle and is essentially a repeat of region 402.

FIG. 4B is a graph depicting the potential energy and kinetic energy of the support structure 102 itself over time during the ideal valve pressure cycle of FIG. 4A. Potential energy is indicated by trace 420 and kinetic energy is indicated by trace 440. The positions of points AD from FIG. 4A are shown in chronological order.

FIG. 4B transfers or imparts a load to the elastic support structure 102 as the prosthetic valve leaflet 110 moves radially inward towards the joined state, and then stores the transmitted load as potential energy. Describes the characteristics of an exemplary embodiment of the valve 100. Tissue (ie, non-artificial) leaflets are too inflatable to carry the load in the same manner. While in the closed position, the potential energy stored in the support structure 102 can then be released in the form of kinetic energy when the valve pressure is less negative.

The embodiment of the support structure 102 is therefore movable from the closed position to the open position well before the valve pressure becomes positive, as in the case of the natural valve. This can be referred to as the "rebound" or "active recoil" characteristic of the support structure 102, which is preceded by a positive transvalve pressure (usually prior to blood flow). Or "faster" compared to the natural valve), often well in advance, returning from the closed position to the open position. Thus, the precursory transition is that the movement of the support structure is not initiated by the leaflet (eg, the support structure is pulled or pulled by the leaflet), and the support structure is initially positive back pressure or blood flow through the valve. Occurs without being forcibly released by.

In FIG. 4B, the potential energy 420 and kinetic energy 440 of the support structure 102 are generally minimal while the valve valve pressure is within region 402. As the valve valve pressure deviates from zero and becomes more negative in region 404, the potential energy 420 begins to increase with an equivalent but opposite slope to the pressure decrease (FIG. 4A). As the pressure becomes more negative, the valve leaflet 110 withstands a higher load from the fluid and accelerates radially inward towards the junction position. The increase in potential energy 420 within region 404 is primarily due to the transfer or application of this load from the valve leaflets 110 to the support structure 102, which stores the potential energy in the form of elastic deformation of the material body of the support structure 102. ..

As the valve pressure shifts from zero to more negative in region 404, the kinetic energy 440 exhibits a spike 442 corresponding to the initial high speed movement of the support structure 102 from the open position to the closed position. At 444, as the support structure 102 elastically deforms towards the closed position, the potential energy 420 increases from zero and the kinetic energy 440 decreases at a non-constant rate of decrease.

At point B, the leaflets 110 touch and enter a fully joined state. This corresponds to a plunge 446 at kinetic energy 440, indicating that the support structure 102 has essentially reached the closed position. Some degree of continuous reduction in kinetic energy occurs within region 406 until point C, where the support structure 102 settles in the closed position. The potential energy 420 reaches its maximum value within region 406 and remains generally constant, generally corresponding to a constant peak of negative valve pressure.

At point C, the valve valve pressure is at its peak negative pressure, and immediately after that, the valve valve pressure becomes less negative (increases). In this embodiment, the stored potential energy 420 begins to be unloaded from the support structure 102 in the form of kinetic energy 440. Thus, a spike in kinetic energy 440 occurs immediately after point C or in response to the valve valve pressure decreasing from the peak negative pressure. The kinetic energy 440 reaches the transition energy 450, which first becomes a plateau and then gradually increases as the potential energy 420 continues to decrease through region 408. In this embodiment, the kinetic energy 440 can be described as behaving substantially like a step function at both points B and C.

The increase in kinetic energy 440, 448, corresponds to the precursory movement of the support structure back towards the open position (further details of this movement will be described later). At point C, the valve leaflets 110 are still fully joined. The valve leaflet 110 leaves the fully joined state as the pressure becomes less negative towards point D. In some embodiments, the valve 100 can be 20% or more open at point D (ie, the valve 100 allows 20% or more of its fluid flow in the normally open state), etc. In one embodiment, the valve 100 can be fully opened at or prior to reaching point D, and in yet other embodiments, the valve 100 reaches the peak positive pressure of the subsequent cycle. Depending on what you do, it will be completely open. This increase 448 in kinetic energy is driven by the unloading of potential energy 420 stored in the form of elastic deformation of the support structure 102. Thus, the support structure 102 has a precursory or active transition (eg,) to or towards its open position before the valve leaflets 110 leave the fully joined state and before blood begins to flow through the interior of the valve 100. , Recoil or recoil). Advantages of this precursor transition 448 can include a significantly reduced pressure gradient or resistance to opening, which in turn results in a smaller effective valve opening area (EOA) and an increase in effective forward blood flow. be able to.

As mentioned above, in the actual operation of the valve 100, the valve valve pressure may not exhibit a constant peak negative pressure as shown in region 406 of FIG. 4A. Alternatively, the valve pressure can exhibit curved or parabolic behavior with a peak negative pressure at the apex. It should be emphasized that in some embodiments the peak negative valvebar pressure is about 120 mmHg, but this is strictly an example and other peak negative pressures may also be exhibited. In the embodiment described with respect to FIG. 4B, the precursor transition 448 begins as soon as the valve pressure is less negative after the peak negative pressure.

However, in other embodiments, the support structure 102 can be configured such that the precursory transition begins at a later time. In some exemplary embodiments, the precursor transition is when the valve valve pressure is 90-99.9% of the peak valve valve pressure and the valve valve pressure is 85-95% of the peak valve valve pressure. When the valve valve pressure is 75 to 90% of the peak valve valve pressure, when the valve valve pressure is 50 to 75% of the peak valve valve pressure, or when the valve valve pressure is 25 to 50% of the peak valve valve pressure. Can sometimes occur.

FIG. 5A illustrates an exemplary embodiment of a support structure 102 with a vector simulating a relative velocity across the surface of the elastic support structure 102 as the structure 102 transitions from a closed position to an open position. It is a side view. In this embodiment, the velocity vector is at the time at which the precursory transition begins (eg, immediately after point C in FIG. 4B). Here, only the anterior half of the support structure 102 is shown and the valve leaflets 110 are omitted (but are present) for ease of illustration. The location where the upstream end 112-1 of the valve leaflet 110-1 would be located is indicated by an arrow.

The support structure 102 has a plurality of first locations 501 and second locations 502 that are aligned with the downstream end 107 of the protrusion 106 and the upstream end 112 of the valve apex 110. In FIG. 5A, the locations of the first locations 501-1 and 501-3 are shown just upstream of the downstream ends 107-1 and 107-3, respectively. The location of the second location 502-1 is indicated just upstream of the upstream valve tip 112-1. The first location 501-1 is at the downstream end 107-along the flange 121 that lies beneath the side wall of the protrusion 106-1 and extends radially outward in line with the end 107-1. It is just upstream of 1. Some asymmetries may be present under normal operation in various embodiments, but embodiments of the valve 100 operate in a symmetrical fashion, with each valve tip 110 and protrusion 106 generally in open position and closure. It reciprocates to and from the position and moves in the same manner.

The longer the velocity vector, the higher the instantaneous velocity. As can be seen, here the relatively highest instantaneous velocities occur along the protrusion 106, especially at the downstream end 107, and in close proximity to it. This is because these are the regions with the highest amount of elastic deformation at the closed position.

In many embodiments, the elastic upstream edge 120 also exhibits movement as the support structure 102 initiates a precursory transition from the closed position to the open position. In the embodiment of FIG. 5A, the upstream edge 120 moves upstream at each of the first locations 501, and the upstream edge 120 simultaneously moves downstream at each of the second locations 502.

This characteristic is shown in FIG. 5B, the flange 121 is shown by the corresponding velocity vector, the size of which is increased compared to FIG. 5A for ease of illustration. The rest of the support structure 102 is contoured without the remaining velocity vector (see FIG. 5A), and the valve leaflet 110 is not shown again for clarity.

In FIG. 5B, the velocity vector has a substantially sinusoidal distribution that is converted into a sinusoidal displacement along the upstream edge 120 around the entire circumference of the valve 100. For example, the area surrounding each first location 501 has the largest size in or near the first location 501 itself, and generally decreases or decreases as the distance from the first location 501 increases on both sides. It has a velocity vector in the downstream direction that is tapered. Conversely, the area surrounding each second location 502 has the largest size in or near the second location 502 itself, and generally as the distance from the second location 502 increases on both sides. Has a velocity vector in the upstream direction, which is diminishing or tapered. Approximately in the middle between each first location 501 and the second location 502 immediately adjacent to it is the third location 503, where the velocity vector reaches zero and is motionless at that location and at this point in time. Indicates that. The place 503 is a pivot point interposed between the oscillation divisions. For each location around the periphery of the upstream edge 120, the velocity vector becomes relatively larger as it travels radially outward from the inner edge of the flange 121 to the outer edge of the flange 121 (3 in FIG. 5B). Indicated by two concentric sequences).

Therefore, in many embodiments, when looking at the edge 120 as a whole, the velocity and motion profile are generally sinusoidal and certain points along the upstream edge 120 are along the upstream edge 120 being inspected. Depending on the location of the point, the displacement can alternate from complete upstream displacement to neutral displacement, complete downstream displacement, and return to neutral displacement. In the closed position, the upstream edge 120 has a sinusoidal surface, the location 501 is displaced relatively downstream and the location 502 is relatively upstream. In the open position, the upstream edge 120 also has a sinusoidal surface, but with complementary or inverse profiles, location 501 is displaced relatively upstream and location 502 is displaced relatively downstream. ing. In the embodiment shown herein, the pivot point location 503 does not suffer relative displacement as the valve 100 transitions between the open and closed positions.

Further, in the present embodiment, the base edge 120 does not have a sinusoidal shape in the neutral position, and is flat or flat. In an alternative embodiment where the base edge 120 is not planar in the neutral position, such as an aortic configuration in which the base edge 120 is scalloped, the sinusoidal displacement then arises from the scalloped neutral position as opposed to the planar neutral position. .. Although velocities and displacements are described as sinusoidal shapes, these velocities and displacements can also be substantially sinusoidal, and one of ordinary skill in the art, after perusing this description, will be substantially sinusoidal. You will easily recognize some of those shapes. In either case, one of ordinary skill in the art will appreciate that the sine function can vary in amplitude and frequency. Also, the manufacture and use of artificial valves is due to manufacturing differences, differences caused by embedding, differences caused by the length of time the valve is embedded (eg, accumulation of substances such as calcification), and / or noise. It is understood that the effects of these deviations on the sine function, which can result in deviations, are within the term "sine wave" as used herein.

5A-5B depict the instantaneous velocity on the support structure 102 at the time when the precursory transition, which may be immediately after point C in FIG. 4B, begins or at any other time as described herein. do. Motion in these directions continues at a speed that ultimately decelerates until the support structure 102 reaches its open position (see FIGS. 2A-2C), which can occur any number of times. For example, when the valve valve pressure becomes positive, if the support structure 102 reaches its open position, the motion in the direction indicated by these vectors begins the precursory transition (eg, the pressure peaks at 90-99). The valve pressure is from 9.9%, peak 85-95%, peak 75-90%, peak 50-75%, peak 25-50%, etc. (immediately after point C in FIG. 4A). It can continue until that time when it becomes positive. Similarly, if the support structure 102 reaches its fully open position when maximum fluid flow occurs in the downstream direction (eg, peak positive pressure), the motion in the direction indicated by these vectors will be from the onset of the precursory transition. It can be continued until the time when the valve pressure becomes positive.

5A-5B depict the speed as the support structure 102 moves from the closed position (see, eg, FIGS. 3A-C) to the open position (see, eg, FIGS. 2A-2C). In these embodiments, as the support structure 102 moves from the open position to the closed position, a similar but opposite movement occurs (not shown). Thus, for example, in each of the velocity vector directions in FIG. 5A, the support structure 102 moves from the open position to the closed position (for example, the protrusion 106 moves inward in the radial direction, and the first place 501 moves in the upstream direction. , The second place 502 moves downstream, etc.) can be reversed to depict the direction of movement. The magnitude of the instantaneous velocity is depicted in FIGS. 5A-5B because the peak positive valve pressure (eg, about 20 mmHg) is generally significantly below the peak negative valve pressure (eg, about 120 mmHg). Will be relatively smaller than the one.

In many embodiments, the downstream end 107 of the support structure 102 exhibits maximum displacement as the structure 102 transitions between the closed and open positions. The downstream end 107 of the support structure also exhibits a relatively high instantaneous velocity as the support structure 102 moves away from the open or closed position.

Embodiments of the valve 100 may have different maximum displacements when measured from the neutral position of the valve (eg, see FIGS. 1A-1B) to the open or closed position, depending on the size of the valve. The following paragraphs describe embodiments with various displacements and velocities obtained from an exemplary trapezius and aortic configuration. An exemplary trapezius configuration has a diameter of 27 mm and a protrusion length of 13.5 mm measured along the central longitudinal axis of the protrusion from a position alongside the valve apex base edge 112 (see FIG. 5A). Was. The exemplary aortic configuration had a diameter of 23 mm and a protrusion length of 510 mm. The velocities and displacements described herein are scaled in a substantially linear fashion between sizes. The various sizes of trapezius and aortic embodiments are described in more detail below.

For mitral valve configurations transitioning from the neutral position to the closed position, in some embodiments, the maximum radial inward displacement (D _MRI ) of the downstream end 107 is 0.45 mm (mm) or greater, and some. In certain embodiments, the D _MRI is 0.50 mm or greater, in some embodiments the D _MRI is 0.55 mm or greater, and in some embodiments the D _MRI is 0.60 mm or greater. Yes, in some embodiments the D _MRI is 0.65 mm or greater, and in some embodiments the D _MRI is 0.70 mm or greater. Depending on the actual implementation, in one exemplary embodiment the D _MRI does not exceed 1.50 mm and in other embodiments the D _MRI does not exceed 0.90 mm.

For mitral valve configurations transitioning from the neutral position to the open position, in some embodiments the maximum radial outward displacement ( _DMRO ) of the downstream end 107 is 0.020 mm or greater, and in some embodiments the maximum radial outward displacement (DMRO) is 0.020 mm or greater. , D _MRO is 0.021 mm or more, and in some embodiments, D _MRO is 0.022 mm or more. Depending on the actual implementation, in one exemplary embodiment the D _MRO does not exceed 0.060 mm and in other exemplary embodiments the D _MRO does not exceed 0.030 mm.

With respect to the aortic valve configuration transitioning from the neutral position to the closed position, in some embodiments, the maximum radial inward displacement (D _MRI ) of the downstream end 107 is 0.31 mm (mm) or greater, and some In embodiments, the D _MRI is 0.35 mm or greater, in some embodiments the D _MRI is 0.38 mm or greater, and in some embodiments the D _MRI is 0.40 mm or greater. In some embodiments, the D _MRI is 0.45 mm or greater, and in some embodiments the D _MRI is 0.50 mm or greater. Depending on the actual implementation, in one exemplary embodiment the D _MRI does not exceed 1.20 mm and in other exemplary embodiments the D _MRI does not exceed 0.60 mm.

In many embodiments, the downstream end 107 of the support structure 102 also exhibits a particular instantaneous velocity when the structure 102 initiates a precursory transition from a closed position to an open position. For mitral valve configurations from closed to open positions, in some embodiments, the instantaneous velocity ( _VICO ) of each downstream end 107 at the onset of the precursory transition is 5.10 mm / sec (mm / sec). s) or greater, in some embodiments the _VICO is 5.20 mm / s or greater, and in some embodiments the _VICO is 5.30 mm / s or greater, in some embodiments. In embodiments, the _VICO is 5.40 mm / s or higher, in some embodiments the _VICO is 5.50 mm / s or higher, and in some embodiments the _VICO is 5.60 mm. _{/ S} In embodiments, the _VICO is 6.20 mm / s or greater, in some embodiments the _VICO is 6.40 mm / s or greater, and in some embodiments the _VICO is 6.60 mm. _{/ S} In morphology, the _VICO is 7.10 mm / s or higher. Depending on the actual implementation, in one exemplary embodiment the VIC O does not exceed _14.50 mm / s and in other exemplary embodiments the _VIC O does not exceed 7.8 mm / s.

For mitral valve configurations transitioning from the open position to the closed position, in some embodiments, the instantaneous velocity ( _VICO ) of each downstream end 107 at the onset of the precursory transition is 4.10 mm / s or greater. In some embodiments, the _VICO is 4.20 mm / s or higher, in some embodiments the _VICO is 4.30 mm / s or higher, and in some embodiments the _VICO is greater than or equal to 4.20 mm / s. Is 4.40 mm / s or higher, and in some embodiments, the _VICO is 4.50 mm / s or higher. Depending on the actual implementation, in one exemplary embodiment the _VIC O does not exceed 10.00 mm / s and in other exemplary embodiments the _VIC O does not exceed 5.00 mm / s.

With respect to the aortic valve configuration transitioning from the closed position to the open position, in some embodiments the VIC _O is 14.60 mm / sec (mm / s) or greater, and in some embodiments the _{VIC O} is. 14.75 mm / s or higher, in some embodiments the _VICO is 15.00 mm / s or higher, and in some embodiments the _VICO is 16.00 mm / s or higher, how many. In one embodiment, the _VICO is 17.00 mm / s or higher, in some embodiments the _VICO is 18.00 mm / s or higher, and in some embodiments the _VICO is greater than or equal to 18.00 mm / s. It is 18.50 mm / s or more. Depending on the actual implementation, in one exemplary embodiment the VIC O does not exceed 40.00 mm / s and in other exemplary embodiments the _VIC O does not exceed _21.00 mm / s.

With respect to the aortic valve configuration transitioning from the open position to the closed position, in some embodiments the _VIC O is 6.10 mm / s or greater, and in some embodiments the VIC O is _6.20 mm / s or greater. In some embodiments, the _VIC O is 6.50 mm / s or greater, in some embodiments the _VIC O is 7.00 mm / s or greater, and in some embodiments, the VIC O is greater than or equal to 7.00 mm / s. The _VICO is 7.50 mm / s or more. Depending on the actual implementation, in one exemplary embodiment the _VIC O does not exceed 15.00 mm / s and in other exemplary embodiments the _VIC O does not exceed 8.5 mm / s.

The properties of the aforementioned embodiments are achieved by a balanced use of material, cross section, stiffness, and elasticity with respect to both the valve leaflets 110 and the support structure 102. For example, if the support structure is made from a plastically deformable material, it will not respond in such a manner. Rather, the support structure will take a deformed shape defined from the load applied by the valve leaflets, but gradually the support structure material relaxes, loses its elasticity and restores to its nominal geometry. Will.

Conversely, for leaflets that are less structurally responsive, each leaflet is substantially deformed, significantly reducing the amount of load applied to the support structure, and thus the precursory transition. Therefore, the potential energy stored in the support structure will be significantly reduced. This is often the case for tissue-based artificial heart valves made from bovine or porcine pericardial tissue, where the leaflets are often highly deformable with a very low modulus of elasticity. These tissue-based valves often have support structures made from relatively rigid substrates such as Elgiroy wire or thick curved sections of Delrin or acetal polymers, which have high rigidity due to the inertia of the cross section. Have.

The amount of valve leaflet extension also affects the mechanism. If the support structure is subject to a very slight, completely closed load, there is no stored potential energy to drive the precursor transition mechanism, and therefore the valve leaflets as the minimum pressure becomes less negative. Will elastically restore, but will not open the valve until the pressure is positive, as the support structure has no restoring force.

In the embodiments described herein, as the valve leaflets 110 join, a load is applied onto the support structure 102, which in turn deforms. The magnitude of the deformation can ensure that there is no additional extension in the plane of the leaflet 110, allowing a precursory transition mechanism to occur. Also, in many embodiments, the base 105 (and upstream base edge 120) is flexible and allows significant movement. As a result in the system to facilitate prodromal transitions, as is the case with substantially rigid double flange configurations, where the base is tightly constrained or prevented from deforming freely. The resulting strain energy will be reduced and the maximum stress level will be significantly increased.

The support structure 102 can be machined from one or more materials (eg, a core structure of one material with a coating of the same or another material). The material is preferably a polymeric material such as polyetheretherketone (PEEK), polyurethane, polyetherimide (PEI) such as ULTEM, etc., one of which is used to form valve tips 110, and the like. used. The flap 110 is also preferably processed from a polymeric material, including any biostable polyurethane and polyurethane composition known in the art (eg, polysiloxane-containing polyurethane, etc.). Examples of polyurethane-containing valve leaflets include US Pat. No. 6,984,700, US Pat. No. 7,262,260, US Pat. No. 7,365,134, and Yilgor et al. "Silicone controlling copolymers: Synthesis, developers and applications", Prog. Polym. Sci. (2013), all of which are incorporated herein by reference in their entirety for any purpose. Materials approaching ideal isotropic non-creep properties are particularly suitable for use in many embodiments.

Although many materials can be used, it is preferred that the selected material has a suitable modulus of elasticity and allows for the loading and elastic deformation properties described herein. In many exemplary embodiments, the modulus of elasticity for the leaflet 110 is in the range of 10-45 megapascals (MPa). In one exemplary embodiment, the modulus of elasticity for the apex 110 is in the range of 20-35 MPa, while in some other exemplary embodiments, the modulus of elasticity for the apex 110 is 23-32 MPa. While still within the range, in yet another exemplary embodiment, the modulus of elasticity for the leaflet 110 is in the range of 25-30 MPa. In many exemplary embodiments, the modulus of elasticity for the support structure 102 is in the range of 3000-5000 MPa. In one exemplary embodiment, the modulus of elasticity for the support structure 102 is in the range of 3300-3500 MPa.

式中、Ｅは、ヤング係数であって、Ｉは、区間慣性であって、Ｐは、下流端１０７における力であって、Ｌは、突起１０６の長さ５１０であって、δは、下流端１０７における変位である。 The embodiment of the support structure 102 is relatively less rigid than the "rigid" valve of the prior art. In many embodiments, the support structure 102 has a stiffness / unit force (RUF) (square mm) of _600-1500 . In another embodiment, the support structure 102 has a _RUF of 900 to 1400, and in yet another embodiment, the support structure 102 has a _RUF of 1100 to 1300. The protrusion 106 can be modeled because the elastic beam and _RUF can be calculated according to (1).

In the equation, E is the Young's modulus, I is the section inertia, P is the force at the downstream end 107, L is the length 510 of the protrusion 106, and δ is the downstream. Displacement at the end 107.

In certain embodiments, the support structure 102 may include a core frame. The valve leaflets 110 can be seamlessly formed on the core frame, such as through casting (eg, immersion casting) or a molding process or otherwise. An exemplary dip casting process suitable for valve tip formation is described herein. The core frame can be machined from suitable materials such as those described herein. This can be done by machining or injection molding. The core frame can then be placed on an immersion mandrel, which has a support structure and the shape of the inner surface of the valve leaflets. The mandrel can be inserted into the polymer solution using a forming device that encloses the core frame and casts the valve leaflets into the desired form.

The core frame and mandrel can be immersed in the polymer solution under both high temperature and humidity and then removed. The methods disclosed herein are not limited to such, but in some exemplary embodiments, the relative humidity (RH) can be in the range of 20-80% and the temperature. Can be in the range of 20-50 ° C. This step, which is integrally formed, can bring together the appearance of the support structure 102 and the valve leaflets 110 in the unfinished state.

The immersion step can be performed only once to reach a fully formed (but unfinished) valve, or multiple times (eg, two, three, or as desired). Can be carried out. In one embodiment, the core frame is machined from a first material (eg, PEEK) that is different from the polymeric material on which the valve leaflets are machined. In that case, it may be desirable to form the leaflets with respect to the core frame only after the core frame has been pre-coated with the leaflet polymer to provide more binding. The core frame can be pre-coated by first immersing the core frame in a valvular polymer having a first viscosity. This can be done with or without a mandrel. When done with a mandrel, the resulting valve leaflets can be removed. The pre-coated core frame can then be placed on the mandrel and at this point re-immersed in the same or relatively higher viscosity valve leaflet polymer. This second immersion can result in the formation of a complete valve acrosome that is integrally formed with the support structure. The use of higher viscosities following lower viscosities can allow the formation of leaflets with the desired thickness, following the formation of a thin precoat that does not significantly distort the shape of the underlying core frame.

The support structure 102 and valve apex 110 can then be trimmed and otherwise finished to achieve accurate and precise edge and surface smoothness. This can occur, for example, through laser cutting, ultrasonic trimming, water knives, mechanical clamshell cutters, and equivalents. The suture cuff can be coupled to the support structure 102 (using any flange 121, if present) and the final device can be packaged in the desired sterile container.

Those skilled in the art will appreciate many of the suitable immersion casting techniques, pressures, and temperatures that are not mentioned herein but are suitable for processing the prosthetic heart valves described herein. Modifications will be easily recognized. Similarly, one of ordinary skill in the art will recognize in the light of this description an alternative to immersion casting that can be used to process the artificial heart valves described herein.

The embodiments of the valve 100 described herein are suitable for implantation in the body of a subject (human or animal). This can be done using any number of medical procedures. Preferably, these embodiments of the valve 100 are for direct implantation into, for example, a trapezius or an aortic annulus using open heart surgery.

In one such exemplary open heart implantation procedure, a replacement valve of appropriate size can be determined, and then an open heart access procedure provides access to the dysfunctional valve of the heart to which it will be replaced. Performed by a surgeon to obtain. The surgeon can then position the selected artificial heart valve 100 in place across the dysfunctional valve and attach the valve 100 to the surrounding tissue. Attachment can occur, for example, by tying the suture cuff to the tissue with one or more sutures. Prior to attachment, if the surgeon determines that the selected valve size is not optimal, different valves with different sizes can be selected and placed in place within the heart. In some other embodiments, the dysfunctional valve can be removed prior to positioning the valve 100 in the intended location. Once the valve 100 is attached, the open heart cavity is closed and the procedure is terminated.

The embodiment of the valve 100 used for open heart surgery is not radially crushable for insertion into an intravascular delivery device (eg, a catheter) or transapical delivery device. However, in other embodiments, the valve 100 is reduced to a sufficient extent to allow insertion of the valve 100 into a properly sized intravascular or transapical delivery device. It can be constructed with a support structure that can be crushed in the radial direction, which allows it to be collapsed.

For most aortic valve replacement configurations, the valve 100 can be mounted to fit into the aortic tissue annulus at the following sizes, ie, 17 mm, 19 mm, 21 mm, 23 mm, 25 mm, and 27 mm. Other sizes, including 18 mm, 20 mm, 22 mm, 24 mm, 26 mm, 28 mm, and 29 mm, can also be implemented, and there are many non-integer sizes among those listed. This dimension is also commonly referred to as the inner diameter of the valve or "ID" and refers to the lateral dimension of the valve at the position corresponding to the valve tip 110. The valve may have an even larger diameter than any location, such as the location of the flange 121. For most mitral valve replacement configurations, the valve 100 can be mounted with any of the following IDs, ie, 23 mm, 25 mm, 27 mm, 29 mm, and 31 mm. Other sizes, including 22 mm, 24 mm, 26 mm, 28 mm, 30 mm, 32 mm, can also be implemented, and there are many non-integer sizes among those listed.

The support structure 102 can take various non-cylindrical shapes, but in all embodiments described herein, the support structure 102 can be substantially cylindrical or cylindrical. As will be appreciated by those skilled in the art, "cylindrical" does not require that the support structure 102 be in the form of a perfect geometric cylinder (eg, a vertical wall oriented perpendicular to a circular cross section). Rather, it requires that the support structure 102 be along part of a hypothetical geometric cylinder (with only slight deviations). For example, the entire inner luminal surface of the support structure 102 (the surface directly adjacent to the blood flow) can be cylindrical as the term is used herein. Similarly, one of ordinary skill in the art understands that a "substantially cylindrical" support structure 102 allows for a greater deviation from a mathematical cylinder than a simple "cylindrical support structure" and is considered to be substantially cylindrical. You will easily recognize those support structures.

The entire support structure 102 can be cylindrical or substantially cylindrical, but also only a portion of the support structure 102 is cylindrical or substantially cylindrical and the rest of the support structure 102 is non-cylindrical. It can also be cylindrical. For example, in certain embodiments, only the portion of the support structure 102 along the curved interface 107 may be cylindrical or substantially cylindrical.

When the support structure 102 is formed from a polymer coated core frame, in some embodiments, only the core frame (either whole or part thereof) may be cylindrical or substantially cylindrical. On the other hand, the outer surface of the polymer coating can be non-cylindrical or non-cylindrical. For example, in some embodiments, the inner lumen surface of the core frame is cylindrical and the outer surface of the polymer coating (along the inner lumen of the core frame) is due to variations in coating thickness. It is substantially cylindrical (or even non-cylindrical).

All of the embodiments of the valve 100 described herein are also provided to healthcare professionals as part of a kit (or set) of artificial valves sized for various tissue annulus dimensions. Can be (or held by a healthcare professional). The size can include any combination of two or more of 17 mm, 18 mm, 19 mm, 20 mm, 21 mm, 22 mm, 23 mm, 24 mm, 25 mm, 26 mm, 27 mm, 28 mm, 29 mm, 30 mm, and 31 mm.

Although the embodiments described herein can provide active assistance in opening and closing valves through the storage and release of energy in response to pressure differences in the bloodstream, these valve embodiments are global. Can be characterized as a "passive" device that is not actively powered by an artificial power source. Some embodiments of actively powered devices include machines used for cardiopulmonary bypass (eg, cardiopulmonary machines) and implantable artificial hearts.

The behavior of the valve 100 can be assessed in various ways. For example, the behavior of the valve 100 can be observed after implantation of the valve 100 in the subject. Transvalve pressure can be measured directly in the subject, for example, by placing catheter-based pressure sensors on both sides of the valve. Alternatively, the behavior of the valve 100 can be assessed by the test valve 100 in the test device, which applies fluid pressure in a manner that simulates the valve pressure with respect to the subject. Furthermore, the behavior of the valve 100 can be assessed by computer simulation, applying an ideal model of valve pressure for the subject, such as that described with respect to FIGS. 4A-B.

Various aspects of this subject are described below in the scrutiny of the embodiments described so far and / or as a complement thereof, where the interrelationships and intercompatibility of the following embodiments are emphasized. To. In other words, emphasis is placed on the fact that each feature of the embodiment can be combined with any other feature unless explicitly stated otherwise or logically likely.

In many embodiments, a plurality of synthetic leaflets, a plurality of processes coupled to the leaflets, and an upstream base of the processes, wherein the process and the base are elastic, the base. An artificial heart valve is provided, which comprises a support structure and. The artificial heart valve can have a closed and open position, and multiple leaflets and support structures move between the closed and open positions.

In one embodiment, the prosthesis is configured to allow the fluid to flow in the appropriate upstream-to-downstream direction when the valvular fluid pressure is positive, with the valvular fluid pressure peaking negative. When in pressure, multiple leaflets can be configured to be in a joined state. The artificial heart valve can be configured such that when the transvalvular fluid pressure is at a negative value below the peak negative pressure, the protrusions automatically initiate the movement from the closed position to the open position.

In certain embodiments, the support structure has a perimeter, the base comprising an edge extending around the perimeter of the support structure. Each flap of the plurality of flaps can have an upstream end and each protrusion of the plurality of protrusions can have a downstream end. In one embodiment, the rim has a first location just upstream of each downstream end of the protrusions and a plurality of second locations on the rim so that the rim has a plurality of first locations on the rim. As present, it can include a second location just upstream of each upstream end of the plurality of valve leaflets, each first in the first time between the movement of the support structure from the closed position to the open position. The first place moves in the upstream direction, and each second place moves in the downstream direction.

In one embodiment, the first time is when the valve valve fluid pressure is 90-99.9% of the peak negative pressure, 85-95% of the peak negative pressure, or 25-75% of the peak negative pressure. .. The first time can be when the valvular fluid pressure is a negative value. In one embodiment, each first location on the rim continuously moves downstream as the valvular fluid pressure transitions from 75% of the peak negative pressure to zero, and each second location on the rim. Move upstream. In one embodiment, each first location on the rim moves downstream in response to the transition of the valvular fluid pressure from a peak negative pressure to a less negative pressure, and each second location on the rim. Moves upstream. Multiple leaflets can begin to detach from the zygosity at the first time. Also, in the first time, each downstream end of the plurality of protrusions can move in the radial outward direction.

In certain embodiments, the support structure comprises a suture cuff and one or less suture cuff flanges.

In certain embodiments, the heart valve is an aortic replacement valve or a trapezius replacement valve, the heart valve comprising exactly three synthetic leaflets. In one embodiment, the heart valve is a trapezius replacement valve with exactly two synthetic leaflets.

In certain embodiments, the support structure is not radially crushable due to placement within the intravascular delivery device. In certain embodiments, the support structure is not radially crushable due to placement within the transapical delivery device.

In one embodiment, the support structure and the flaps are made of the same material. In one embodiment, the support structure comprises a coating and the plurality of valve leaflets are a continuation of the coating. Multiple leaflets can be polymer.

In certain embodiments, the flaps are not sutured to the support structure. Multiple leaflets can be seamlessly coupled to the support structure. Multiple leaflets and support structures can be monolithic.

In many embodiments, the artificial heart valve is not part of a cardiopulmonary bypass machine or an implantable artificial heart, or the artificial heart valve is not powered by an artificial power source.

In certain embodiments, the support structure has an inner diameter selected from the group consisting of 17 mm (mm), 19 mm, 21 mm, 23 mm, 25 mm, 27 mm, 29 mm, and 31 mm.

In certain embodiments, the plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 10 to 45 megapascals (MPa). be able to. In certain embodiments, the first elasticity can be in the range of 20-35 MPa. In certain embodiments, the first elasticity can be in the range of 25-30 MPa. In certain embodiments, the second elasticity can be in the range of 3000-5000 MPa. In certain embodiments, the second elasticity can be in the range of 3300-3500 MPa.

In certain embodiments, the support structure can have a stiffness / unit force of 600-1500 mm2. In certain embodiments, the support structure can have a stiffness / unit force of 900 to 1400 mm2. In certain embodiments, the support structure can have a stiffness / unit force of 1100 to 1300 mm2.

Each of the plurality of protrusions can have a downstream end. In one trapezius embodiment, each downstream end can exhibit an instantaneous velocity ( _VICO ) of 5.10 mm / sec (mm / s) or higher, depending on the transition from the closed position to the open position. In various embodiments, the _VICO can be any and range of a plurality of values from 5.10 mm / s to 14.50 mm / s. In certain embodiments, the downstream ends can each exhibit an instantaneous velocity ( _VICO ) of 4.10 mm / sec (mm / s) or higher, depending on the transition from the open position to the closed position. In various embodiments, the _VICO can be any and range of a plurality of values from 4.10 mm / s to 10.00 mm / s.

In one aortic embodiment, each downstream end can exhibit an instantaneous velocity ( _VICO ) of 14.60 mm / sec (mm / s) or higher, depending on the transition from the closed position to the open position. In various embodiments, the _VICO can be any and range of multiple values from 14.60 mm / s to 40.00 mm / s. In certain embodiments, the downstream ends can each exhibit an instantaneous velocity ( _VICO ) of 6.10 mm / sec (mm / s) or higher, depending on the transition from the open position to the closed position. In various embodiments, the _VICO can be any and range of a plurality of values from 6.10 mm / s to 15.00 mm / s.

The artificial heart valve can have a closed, neutral, and open position, and multiple leaflets and support structures transition between the closed position, the neutral position, and the open position during valve operation. .. In one trapezius embodiment, each downstream end can move inward by 0.45 mm (mm) or more in the transition from the neutral position to the closed position. In various embodiments, the downstream ends can each move inward by 0.45 mm to 1.50 mm. In one aortic embodiment, each downstream end can move inward by 0.31 millimeters (mm) or more in the transition from the neutral position to the closed position. In various embodiments, the downstream ends can each move inward by 0.31 mm to 1.20 mm.

If a range of values is provided, the lower bound between the upper bound and the lower bound of the range and any other stated value or intervening value within the stated range, unless explicitly indicated otherwise by the context. Each intervening value up to one tenth of the unit of is included within the present disclosure and can be claimed as a single value or in a smaller range. If the stated scope includes one or both of the limits, then a scope that excludes one or both of those included limits is also included within the present disclosure.

If a discrete value or range of values is provided, the value or range of values may be claimed more broadly as a discrete number or range of numbers, unless otherwise indicated. For example, each value or range of values provided herein may be claimed as an approximation, and this paragraph serves as a precursor and written support for the introduction of the claims, from time to time. Each such value or range of values is listed as "approximately" that value, "approximately" that range of values, "about" that value, and / or "about" that range of values. Conversely, if a value or range of values is described as an approximation or generalization, eg, approximately X or about X, then the value or range of values is discrete without using such broad terms. Can be billed.

However, the present specification implies that the subject matter disclosed herein is limited to a particular value or range of values, unless the claims expressly list the value or range of values. It should not be interpreted in any way. Values or ranges of values are provided herein solely as examples.

All features, elements, components, functions, and steps described with respect to any of the embodiments provided herein may be freely combined and substituted with those from any other embodiment. Note that it is intended. Where a feature, element, component, function, or step is described with respect to only one embodiment, the feature, element, component, function, or step is described herein unless otherwise explicitly stated. It should be understood that it can be used in combination with all other embodiments described in the book. This paragraph therefore combines features, elements, components, functions, and steps from different embodiments from time to time, or substitutes features, elements, components, functions, and steps from one embodiment for another. (Even if the description below does not explicitly state that such a combination or substitution is possible in a particular case) as a precursor to the introduction of the claims and as a written support. Fulfill. Explicit enumeration of all possible combinations and substitutions, in particular, given that such combinations and substitutions are readily recognized by those of skill in the art, is expressly overburdened. Be recognized.

As used herein and in the accompanying claims, the singular forms "a", "an", and "the" include plural references unless otherwise determined by context.

The embodiments are subject to various modifications and alternatives, the specific embodiments thereof are shown in the drawings and described in detail herein. However, it is understood that these embodiments are not limited to the particular embodiments disclosed, and in contrast, these embodiments cover all modifications, equivalents, and alternatives within the spirit of the present disclosure. I want to be. Further, as in the passive limitation, where any feature, function, step, or element of the embodiment defines the scope of the invention by a feature, function, step, or element that is not within its scope. It may be enumerated or added.

Claims (31)

It ’s an artificial heart valve.
Multiple leaflets, each of which is synthetic, with a leaflet,
It is a support structure, and the support structure is
With the plurality of protrusions coupled to the plurality of leaflets,
An upstream base of the plurality of protrusions, wherein the plurality of protrusions and the base are elastic, with a support structure comprising a base.
The artificial heart valve has a closed position and an open position, and the plurality of valve tips and the support structure move between the closed position and the open position.
The artificial heart valve is configured to allow the fluid to flow in the appropriate upstream-to-downstream direction when the transvalve fluid pressure is positive, and the transvalve fluid pressure is the peak negative pressure. When the plurality of valve leaflets are configured to be in a joined state,
The artificial heart valve is configured such that when the transvalve fluid pressure is a negative value less than the peak negative pressure, the plurality of protrusions automatically start moving from the closed position to the open position. ,
The plurality of valve leaflets have a first elasticity, the support structure has a second elasticity, and the first elasticity is in the range of 10 to 45 megapascals (MPa). The second elasticity is an artificial heart valve in the range of 3000 to 5000 MPa . The artificial heart valve according to claim 1, wherein the support structure has a peripheral edge, and an upstream edge extends around the peripheral edge of the support structure. Each valve tip of the plurality of valve leaflets has an upstream end, each protrusion of the plurality of protrusions has a downstream end, and the upstream edge has a downstream end.
A first location upstream of each downstream end of the plurality of protrusions, such that the plurality of first locations are on the upstream edge.
Provided with a second location upstream of each upstream end of the plurality of valve leaflets so that the plurality of second locations reside on the upstream edge.
In the first time between the movement of the support structure from the closed position to the open position, each first location moves upstream and each second location moves downstream, claim. Item 2. The artificial heart valve according to Item 2. The artificial heart valve according to claim 3, wherein the first time is when the transvalve fluid pressure is 90 to 99.9% of the peak negative pressure. The artificial heart valve according to claim 3, wherein the first time is when the transvalve fluid pressure is 85 to 95% of the peak negative pressure. The artificial heart valve according to claim 3, wherein the first time is when the transvalve fluid pressure is 25 to 75% of the peak negative pressure. The artificial heart valve according to claim 3, wherein the first time is when the transvalve fluid pressure is the negative value. As the valve valve fluid pressure transitions from 75% of the peak negative pressure to zero, each first location on the upstream edge moves downstream and each second location on the upstream edge continues. The artificial heart valve according to claim 3, which moves in the upstream direction. In immediate response to the transition of the valve valve fluid pressure from the peak negative pressure to the less negative pressure, each first location on the upstream edge moves downstream and each second on the upstream edge. The artificial heart valve according to claim 3, wherein the location moves in the upstream direction. The artificial heart valve according to claim 3, wherein the plurality of leaflets begin to detach from the zygosity at the first time. The artificial heart valve according to claim 3, wherein at the first time, each downstream end of the plurality of protrusions moves in the radial outward direction. The artificial heart valve according to any one of claims 1-11, wherein the support structure comprises a suture cuff and one or less suture cuff flanges. The artificial heart valve according to any one of claims 1-12, wherein the artificial heart valve is an aortic replacement valve or a mitral replacement valve, and the artificial heart valve includes three synthetic valve tips. The artificial heart valve according to any one of claims 1-12, wherein the artificial heart valve is a trapezius replacement valve having two synthetic valve tips. The artificial heart valve according to any one of claims 1-14, wherein the support structure is not radially crushable for placement in an intravascular delivery device. The artificial heart valve according to any one of claims 1-15, wherein the support structure is not radially crushable due to placement within the transapical delivery device. The artificial heart valve according to any one of claims 1-16, wherein the support structure and the plurality of flaps are formed of the same material. The artificial heart valve according to any one of claims 1-17, wherein the support structure comprises a coating, wherein the plurality of flaps are continuations of the coating. The artificial heart valve according to any one of claims 1-18, wherein the plurality of valve leaflets are not sutured to the support structure. The artificial heart valve according to any one of claims 1-19, wherein the plurality of leaflets are seamlessly coupled to the support structure. The artificial heart valve according to any one of claims 1-20, wherein the plurality of leaflets and the support structure are monolithic bodies. The artificial heart valve according to any one of claims 1-21, wherein the artificial heart valve is not a part of a cardiopulmonary bypass machine or an implantable artificial heart. The artificial heart valve according to any one of claims 1-22, wherein the artificial heart valve is not powered by an artificial power source. The artificial heart valve according to any one of claims 1-23, wherein the support structure has an inner diameter selected from the group consisting of 17 mm (mm), 19 mm, 21 mm, 23 mm, 25 mm, 27 mm, 29 mm, and 31 mm. .. The artificial heart valve according to any one of claims 1-24, wherein the plurality of flaps are polymers. The artificial according to any one of claims 1-25, wherein the first elasticity is in the range of 20 to 35 megapascals (MPa) and the second elasticity is in the range of 3300 to 3500 MPa. Heart valve. The artificial according to any one of claims 1-25, wherein the first elasticity is in the range of 25 to 30 megapascals (MPa) and the second elasticity is in the range of 3300 to 3500 MPa. Heart valve. The artificial heart valve according to any one of claims 1-27 , wherein the support structure has a rigidity / unit force of 600 to 1500 mm2. The artificial heart valve according to any one of claims 1-27 , wherein the support structure has a rigidity / unit force of 900 to 1400 mm2. The artificial heart valve according to any one of claims 1-27 , wherein the support structure has a rigidity / unit force of 1100 to 1300 mm2. Inventions having the novelty and inventive step described herein.

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